PURPOSE: Solid tumors contain microenvironmental regions of hypoxia that present a barrier to traditional radiotherapy and chemotherapy, and this work describes a novel approach to circumvent hypoxia. We propose to overcome hypoxia by augmenting the effectiveness of drugs that are designed to specifically kill hypoxic tumor cells. EXPERIMENTAL DESIGN: We have constructed RKO colorectal tumor cells that express a small RNA hairpin that specifically knocks down the hypoxia-inducible factor 1a (HIF1a) transcription factor. We have used these cells in vitro to determine the effect of HIF1 on cellular sensitivity to the hypoxic cytotoxin PR-104, and its role in cellular oxygen consumption in response to the pyruvate dehydrogenase kinase inhibitor dichloroacetate (DCA). We have further used these cells in vivo in xenografted tumors to determine the role of HIF1 in regulating tumor hypoxia in response to DCA using (18)F-fluoroazomycin arabinoside positron emission tomography, and its role in regulating tumor sensitivity to the combination of DCA and PR-104. RESULTS: HIF1 does not affect cellular sensitivity to PR-104 in vitro. DCA transiently increases cellular oxygen consumption in vitro and increases the extent of tumor hypoxia in vivo as measured with (18)F-fluoroazomycin arabinoside positron emission tomography. Furthermore, we show that DCA-dependent alterations in hypoxia increase the antitumor activity of the next-generation hypoxic cytotoxin PR-104. CONCLUSIONS: DCA interferes with the HIF-dependent "adaptive response," which limits mitochondrial oxygen consumption. This approach transiently increases tumor hypoxia and represents an important method to improve antitumor efficacy of hypoxia-targeted agents, without increasing toxicity to oxygenated normal tissue.
PURPOSE:Solid tumors contain microenvironmental regions of hypoxia that present a barrier to traditional radiotherapy and chemotherapy, and this work describes a novel approach to circumvent hypoxia. We propose to overcome hypoxia by augmenting the effectiveness of drugs that are designed to specifically kill hypoxic tumor cells. EXPERIMENTAL DESIGN: We have constructed RKO colorectal tumor cells that express a small RNA hairpin that specifically knocks down the hypoxia-inducible factor 1a (HIF1a) transcription factor. We have used these cells in vitro to determine the effect of HIF1 on cellular sensitivity to the hypoxic cytotoxin PR-104, and its role in cellular oxygen consumption in response to the pyruvate dehydrogenase kinase inhibitor dichloroacetate (DCA). We have further used these cells in vivo in xenografted tumors to determine the role of HIF1 in regulating tumor hypoxia in response to DCA using (18)F-fluoroazomycin arabinoside positron emission tomography, and its role in regulating tumor sensitivity to the combination of DCA and PR-104. RESULTS:HIF1 does not affect cellular sensitivity to PR-104 in vitro. DCA transiently increases cellular oxygen consumption in vitro and increases the extent of tumor hypoxia in vivo as measured with (18)F-fluoroazomycin arabinoside positron emission tomography. Furthermore, we show that DCA-dependent alterations in hypoxia increase the antitumor activity of the next-generation hypoxic cytotoxin PR-104. CONCLUSIONS:DCA interferes with the HIF-dependent "adaptive response," which limits mitochondrial oxygen consumption. This approach transiently increases tumor hypoxia and represents an important method to improve antitumor efficacy of hypoxia-targeted agents, without increasing toxicity to oxygenated normal tissue.
Authors: Sébastien Bonnet; Stephen L Archer; Joan Allalunis-Turner; Alois Haromy; Christian Beaulieu; Richard Thompson; Christopher T Lee; Gary D Lopaschuk; Lakshmi Puttagunta; Sandra Bonnet; Gwyneth Harry; Kyoko Hashimoto; Christopher J Porter; Miguel A Andrade; Bernard Thebaud; Evangelos D Michelakis Journal: Cancer Cell Date: 2007-01 Impact factor: 31.743
Authors: Morand Piert; Hans-Jürgen Machulla; Maria Picchio; Gerald Reischl; Sybille Ziegler; Piyush Kumar; Hans-Jürgen Wester; Roswitha Beck; Alexander J B McEwan; Leonard I Wiebe; Markus Schwaiger Journal: J Nucl Med Date: 2005-01 Impact factor: 10.057
Authors: Roswitha Beck; Barbara Röper; Janette Maria Carlsen; Marc Cornelis Huisman; Julia Aloisia Lebschi; Nicolaus Andratschke; Maria Picchio; Michael Souvatzoglou; Hans-Jürgen Machulla; Morand Piert Journal: J Nucl Med Date: 2007-06 Impact factor: 10.057
Authors: Adam V Patterson; Dianne M Ferry; Shelley J Edmunds; Yongchuan Gu; Rachelle S Singleton; Kashyap Patel; Susan M Pullen; Kevin O Hicks; Sophie P Syddall; Graham J Atwell; Shangjin Yang; William A Denny; William R Wilson Journal: Clin Cancer Res Date: 2007-07-01 Impact factor: 12.531
Authors: A Yaromina; S Meyer; C Fabian; K Zaleska; U G A Sattler; L A Kunz-Schughart; W Mueller-Klieser; D Zips; M Baumann Journal: Strahlenther Onkol Date: 2012-02-16 Impact factor: 3.621
Authors: Albert L Shroads; Taimour Langaee; Bonnie S Coats; Tracie L Kurtz; John R Bullock; David Weithorn; Yan Gong; David A Wagner; David A Ostrov; Julie A Johnson; Peter W Stacpoole Journal: J Clin Pharmacol Date: 2011-06-03 Impact factor: 3.126
Authors: Keith R Laderoute; Joy M Calaoagan; Wan-Ru Chao; Dominc Dinh; Nicholas Denko; Sarah Duellman; Jessica Kalra; Xiaohe Liu; Ioanna Papandreou; Lidia Sambucetti; Laszlo G Boros Journal: J Biol Chem Date: 2014-07-03 Impact factor: 5.157
Authors: Rehan Ali; Sandeep Apte; Marta Vilalta; Murugesan Subbarayan; Zheng Miao; Frederick T Chin; Edward E Graves Journal: PLoS One Date: 2015-10-02 Impact factor: 3.240
Authors: W Y Sanchez; S L McGee; T Connor; B Mottram; A Wilkinson; J P Whitehead; S Vuckovic; L Catley Journal: Br J Cancer Date: 2013-03-26 Impact factor: 7.640